src/third_party/llvm-project/compiler-rt/lib/esan/esan.cpp - cobalt - Git at Google

 //===-- esan.cpp ----------------------------------------------------------===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // This file is a part of EfficiencySanitizer, a family of performance tuners.
 //
 // Main file (entry points) for the Esan run-time.
 //===----------------------------------------------------------------------===//

 #include "esan.h"
 #include "esan_flags.h"
 #include "esan_interface_internal.h"
 #include "esan_shadow.h"
 #include "cache_frag.h"
 #include "sanitizer_common/sanitizer_common.h"
 #include "sanitizer_common/sanitizer_flag_parser.h"
 #include "sanitizer_common/sanitizer_flags.h"
 #include "working_set.h"

 // See comment below.
 extern "C" {
 extern void __cxa_atexit(void (*function)(void));
 }

 namespace __esan {

 bool EsanIsInitialized;
 bool EsanDuringInit;
 ShadowMapping Mapping;

 // Different tools use different scales within the same shadow mapping scheme.
 // The scale used here must match that used by the compiler instrumentation.
 // This array is indexed by the ToolType enum.
 static const uptr ShadowScale[] = {
   0, // ESAN_None.
   2, // ESAN_CacheFrag: 4B:1B, so 4 to 1 == >>2.
   6, // ESAN_WorkingSet: 64B:1B, so 64 to 1 == >>6.
 };

 // We are combining multiple performance tuning tools under the umbrella of
 // one EfficiencySanitizer super-tool.  Most of our tools have very similar
 // memory access instrumentation, shadow memory mapping, libc interception,
 // etc., and there is typically more shared code than distinct code.
 //
 // We are not willing to dispatch on tool dynamically in our fastpath
 // instrumentation: thus, which tool to use is a static option selected
 // at compile time and passed to __esan_init().
 //
 // We are willing to pay the overhead of tool dispatch in the slowpath to more
 // easily share code.  We expect to only come here rarely.
 // If this becomes a performance hit, we can add separate interface
 // routines for each subtool (e.g., __esan_cache_frag_aligned_load_4).
 // But for libc interceptors, we'll have to do one of the following:
 // A) Add multiple-include support to sanitizer_common_interceptors.inc,
 //    instantiate it separately for each tool, and call the selected
 //    tool's intercept setup code.
 // B) Build separate static runtime libraries, one for each tool.
 // C) Completely split the tools into separate sanitizers.

 void processRangeAccess(uptr PC, uptr Addr, int Size, bool IsWrite) {
   VPrintf(3, "in esan::%s %p: %c %p %d\n", __FUNCTION__, PC,
           IsWrite ? 'w' : 'r', Addr, Size);
   if (__esan_which_tool == ESAN_CacheFrag) {
     // TODO(bruening): add shadow mapping and update shadow bits here.
     // We'll move this to cache_frag.cpp once we have something.
   } else if (__esan_which_tool == ESAN_WorkingSet) {
     processRangeAccessWorkingSet(PC, Addr, Size, IsWrite);
   }
 }

 bool processSignal(int SigNum, void (*Handler)(int), void (**Result)(int)) {
   if (__esan_which_tool == ESAN_WorkingSet)
     return processWorkingSetSignal(SigNum, Handler, Result);
   return true;
 }

 bool processSigaction(int SigNum, const void *Act, void *OldAct) {
   if (__esan_which_tool == ESAN_WorkingSet)
     return processWorkingSetSigaction(SigNum, Act, OldAct);
   return true;
 }

 bool processSigprocmask(int How, void *Set, void *OldSet) {
   if (__esan_which_tool == ESAN_WorkingSet)
     return processWorkingSetSigprocmask(How, Set, OldSet);
   return true;
 }

 #if SANITIZER_DEBUG
 static bool verifyShadowScheme() {
   // Sanity checks for our shadow mapping scheme.
   uptr AppStart, AppEnd;
   if (Verbosity() >= 3) {
     for (int i = 0; getAppRegion(i, &AppStart, &AppEnd); ++i) {
       VPrintf(3, "App #%d: [%zx-%zx) (%zuGB)\n", i, AppStart, AppEnd,
               (AppEnd - AppStart) >> 30);
     }
   }
   for (int Scale = 0; Scale < 8; ++Scale) {
     Mapping.initialize(Scale);
     if (Verbosity() >= 3) {
       VPrintf(3, "\nChecking scale %d\n", Scale);
       uptr ShadowStart, ShadowEnd;
       for (int i = 0; getShadowRegion(i, &ShadowStart, &ShadowEnd); ++i) {
         VPrintf(3, "Shadow #%d: [%zx-%zx) (%zuGB)\n", i, ShadowStart,
                 ShadowEnd, (ShadowEnd - ShadowStart) >> 30);
       }
       for (int i = 0; getShadowRegion(i, &ShadowStart, &ShadowEnd); ++i) {
         VPrintf(3, "Shadow(Shadow) #%d: [%zx-%zx)\n", i,
                 appToShadow(ShadowStart), appToShadow(ShadowEnd - 1)+1);
       }
     }
     for (int i = 0; getAppRegion(i, &AppStart, &AppEnd); ++i) {
       DCHECK(isAppMem(AppStart));
       DCHECK(!isAppMem(AppStart - 1));
       DCHECK(isAppMem(AppEnd - 1));
       DCHECK(!isAppMem(AppEnd));
       DCHECK(!isShadowMem(AppStart));
       DCHECK(!isShadowMem(AppEnd - 1));
       DCHECK(isShadowMem(appToShadow(AppStart)));
       DCHECK(isShadowMem(appToShadow(AppEnd - 1)));
       // Double-shadow checks.
       DCHECK(!isShadowMem(appToShadow(appToShadow(AppStart))));
       DCHECK(!isShadowMem(appToShadow(appToShadow(AppEnd - 1))));
     }
     // Ensure no shadow regions overlap each other.
     uptr ShadowAStart, ShadowBStart, ShadowAEnd, ShadowBEnd;
     for (int i = 0; getShadowRegion(i, &ShadowAStart, &ShadowAEnd); ++i) {
       for (int j = 0; getShadowRegion(j, &ShadowBStart, &ShadowBEnd); ++j) {
         DCHECK(i == j || ShadowAStart >= ShadowBEnd ||
                ShadowAEnd <= ShadowBStart);
       }
     }
   }
   return true;
 }
 #endif

 uptr VmaSize;

 static void initializeShadow() {
   verifyAddressSpace();

   // This is based on the assumption that the intial stack is always allocated
   // in the topmost segment of the user address space and the assumption
   // holds true on all the platforms currently supported.
   VmaSize =
     (MostSignificantSetBitIndex(GET_CURRENT_FRAME()) + 1);

   DCHECK(verifyShadowScheme());

   Mapping.initialize(ShadowScale[__esan_which_tool]);

   VPrintf(1, "Shadow scale=%d offset=%p\n", Mapping.Scale, Mapping.Offset);

   uptr ShadowStart, ShadowEnd;
   for (int i = 0; getShadowRegion(i, &ShadowStart, &ShadowEnd); ++i) {
     VPrintf(1, "Shadow #%d: [%zx-%zx) (%zuGB)\n", i, ShadowStart, ShadowEnd,
             (ShadowEnd - ShadowStart) >> 30);

     uptr Map = 0;
     if (__esan_which_tool == ESAN_WorkingSet) {
       // We want to identify all shadow pages that are touched so we start
       // out inaccessible.
       Map = (uptr)MmapFixedNoAccess(ShadowStart, ShadowEnd- ShadowStart,
                                     "shadow");
     } else {
       if (MmapFixedNoReserve(ShadowStart, ShadowEnd - ShadowStart, "shadow"))
         Map = ShadowStart;
     }
     if (Map != ShadowStart) {
       Printf("FATAL: EfficiencySanitizer failed to map its shadow memory.\n");
       Die();
     }

     if (common_flags()->no_huge_pages_for_shadow)
       NoHugePagesInRegion(ShadowStart, ShadowEnd - ShadowStart);
     if (common_flags()->use_madv_dontdump)
       DontDumpShadowMemory(ShadowStart, ShadowEnd - ShadowStart);

     // TODO: Call MmapNoAccess() on in-between regions.
   }
 }

 void initializeLibrary(ToolType Tool) {
   // We assume there is only one thread during init, but we need to
   // guard against double-init when we're (re-)called from an
   // early interceptor.
   if (EsanIsInitialized || EsanDuringInit)
     return;
   EsanDuringInit = true;
   CHECK(Tool == __esan_which_tool);
   SanitizerToolName = "EfficiencySanitizer";
   CacheBinaryName();
   initializeFlags();

   // Intercepting libc _exit or exit via COMMON_INTERCEPTOR_ON_EXIT only
   // finalizes on an explicit exit call by the app.  To handle a normal
   // exit we register an atexit handler.
   ::__cxa_atexit((void (*)())finalizeLibrary);

   VPrintf(1, "in esan::%s\n", __FUNCTION__);
   if (__esan_which_tool <= ESAN_None || __esan_which_tool >= ESAN_Max) {
     Printf("ERROR: unknown tool %d requested\n", __esan_which_tool);
     Die();
   }

   initializeShadow();
   if (__esan_which_tool == ESAN_WorkingSet)
     initializeShadowWorkingSet();

   initializeInterceptors();

   if (__esan_which_tool == ESAN_CacheFrag) {
     initializeCacheFrag();
   } else if (__esan_which_tool == ESAN_WorkingSet) {
     initializeWorkingSet();
   }

   EsanIsInitialized = true;
   EsanDuringInit = false;
 }

 int finalizeLibrary() {
   VPrintf(1, "in esan::%s\n", __FUNCTION__);
   if (__esan_which_tool == ESAN_CacheFrag) {
     return finalizeCacheFrag();
   } else if (__esan_which_tool == ESAN_WorkingSet) {
     return finalizeWorkingSet();
   }
   return 0;
 }

 void reportResults() {
   VPrintf(1, "in esan::%s\n", __FUNCTION__);
   if (__esan_which_tool == ESAN_CacheFrag) {
     return reportCacheFrag();
   } else if (__esan_which_tool == ESAN_WorkingSet) {
     return reportWorkingSet();
   }
 }

 void processCompilationUnitInit(void *Ptr) {
   VPrintf(2, "in esan::%s\n", __FUNCTION__);
   if (__esan_which_tool == ESAN_CacheFrag) {
     DCHECK(Ptr != nullptr);
     processCacheFragCompilationUnitInit(Ptr);
   } else {
     DCHECK(Ptr == nullptr);
   }
 }

 // This is called when the containing module is unloaded.
 // For the main executable module, this is called after finalizeLibrary.
 void processCompilationUnitExit(void *Ptr) {
   VPrintf(2, "in esan::%s\n", __FUNCTION__);
   if (__esan_which_tool == ESAN_CacheFrag) {
     DCHECK(Ptr != nullptr);
     processCacheFragCompilationUnitExit(Ptr);
   } else {
     DCHECK(Ptr == nullptr);
   }
 }

 unsigned int getSampleCount() {
   VPrintf(1, "in esan::%s\n", __FUNCTION__);
   if (__esan_which_tool == ESAN_WorkingSet) {
     return getSampleCountWorkingSet();
   }
   return 0;
 }

 } // namespace __esan
	//===-- esan.cpp ----------------------------------------------------------===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This file is a part of EfficiencySanitizer, a family of performance tuners.
	//
	// Main file (entry points) for the Esan run-time.
	//===----------------------------------------------------------------------===//

	#include "esan.h"
	#include "esan_flags.h"
	#include "esan_interface_internal.h"
	#include "esan_shadow.h"
	#include "cache_frag.h"
	#include "sanitizer_common/sanitizer_common.h"
	#include "sanitizer_common/sanitizer_flag_parser.h"
	#include "sanitizer_common/sanitizer_flags.h"
	#include "working_set.h"

	// See comment below.
	extern "C" {
	extern void __cxa_atexit(void (*function)(void));
	}

	namespace __esan {

	bool EsanIsInitialized;
	bool EsanDuringInit;
	ShadowMapping Mapping;

	// Different tools use different scales within the same shadow mapping scheme.
	// The scale used here must match that used by the compiler instrumentation.
	// This array is indexed by the ToolType enum.
	static const uptr ShadowScale[] = {
	0, // ESAN_None.
	2, // ESAN_CacheFrag: 4B:1B, so 4 to 1 == >>2.
	6, // ESAN_WorkingSet: 64B:1B, so 64 to 1 == >>6.
	};

	// We are combining multiple performance tuning tools under the umbrella of
	// one EfficiencySanitizer super-tool. Most of our tools have very similar
	// memory access instrumentation, shadow memory mapping, libc interception,
	// etc., and there is typically more shared code than distinct code.
	//
	// We are not willing to dispatch on tool dynamically in our fastpath
	// instrumentation: thus, which tool to use is a static option selected
	// at compile time and passed to __esan_init().
	//
	// We are willing to pay the overhead of tool dispatch in the slowpath to more
	// easily share code. We expect to only come here rarely.
	// If this becomes a performance hit, we can add separate interface
	// routines for each subtool (e.g., __esan_cache_frag_aligned_load_4).
	// But for libc interceptors, we'll have to do one of the following:
	// A) Add multiple-include support to sanitizer_common_interceptors.inc,
	// instantiate it separately for each tool, and call the selected
	// tool's intercept setup code.
	// B) Build separate static runtime libraries, one for each tool.
	// C) Completely split the tools into separate sanitizers.

	void processRangeAccess(uptr PC, uptr Addr, int Size, bool IsWrite) {
	VPrintf(3, "in esan::%s %p: %c %p %d\n", __FUNCTION__, PC,
	IsWrite ? 'w' : 'r', Addr, Size);
	if (__esan_which_tool == ESAN_CacheFrag) {
	// TODO(bruening): add shadow mapping and update shadow bits here.
	// We'll move this to cache_frag.cpp once we have something.
	} else if (__esan_which_tool == ESAN_WorkingSet) {
	processRangeAccessWorkingSet(PC, Addr, Size, IsWrite);
	}
	}

	bool processSignal(int SigNum, void (Handler)(int), void (*Result)(int)) {
	if (__esan_which_tool == ESAN_WorkingSet)
	return processWorkingSetSignal(SigNum, Handler, Result);
	return true;
	}

	bool processSigaction(int SigNum, const void Act, void OldAct) {
	if (__esan_which_tool == ESAN_WorkingSet)
	return processWorkingSetSigaction(SigNum, Act, OldAct);
	return true;
	}

	bool processSigprocmask(int How, void Set, void OldSet) {
	if (__esan_which_tool == ESAN_WorkingSet)
	return processWorkingSetSigprocmask(How, Set, OldSet);
	return true;
	}

	#if SANITIZER_DEBUG
	static bool verifyShadowScheme() {
	// Sanity checks for our shadow mapping scheme.
	uptr AppStart, AppEnd;
	if (Verbosity() >= 3) {
	for (int i = 0; getAppRegion(i, &AppStart, &AppEnd); ++i) {
	VPrintf(3, "App #%d: [%zx-%zx) (%zuGB)\n", i, AppStart, AppEnd,
	(AppEnd - AppStart) >> 30);
	}
	}
	for (int Scale = 0; Scale < 8; ++Scale) {
	Mapping.initialize(Scale);
	if (Verbosity() >= 3) {
	VPrintf(3, "\nChecking scale %d\n", Scale);
	uptr ShadowStart, ShadowEnd;
	for (int i = 0; getShadowRegion(i, &ShadowStart, &ShadowEnd); ++i) {
	VPrintf(3, "Shadow #%d: [%zx-%zx) (%zuGB)\n", i, ShadowStart,
	ShadowEnd, (ShadowEnd - ShadowStart) >> 30);
	}
	for (int i = 0; getShadowRegion(i, &ShadowStart, &ShadowEnd); ++i) {
	VPrintf(3, "Shadow(Shadow) #%d: [%zx-%zx)\n", i,
	appToShadow(ShadowStart), appToShadow(ShadowEnd - 1)+1);
	}
	}
	for (int i = 0; getAppRegion(i, &AppStart, &AppEnd); ++i) {
	DCHECK(isAppMem(AppStart));
	DCHECK(!isAppMem(AppStart - 1));
	DCHECK(isAppMem(AppEnd - 1));
	DCHECK(!isAppMem(AppEnd));
	DCHECK(!isShadowMem(AppStart));
	DCHECK(!isShadowMem(AppEnd - 1));
	DCHECK(isShadowMem(appToShadow(AppStart)));
	DCHECK(isShadowMem(appToShadow(AppEnd - 1)));
	// Double-shadow checks.
	DCHECK(!isShadowMem(appToShadow(appToShadow(AppStart))));
	DCHECK(!isShadowMem(appToShadow(appToShadow(AppEnd - 1))));
	}
	// Ensure no shadow regions overlap each other.
	uptr ShadowAStart, ShadowBStart, ShadowAEnd, ShadowBEnd;
	for (int i = 0; getShadowRegion(i, &ShadowAStart, &ShadowAEnd); ++i) {
	for (int j = 0; getShadowRegion(j, &ShadowBStart, &ShadowBEnd); ++j) {
	DCHECK(i == j \|\| ShadowAStart >= ShadowBEnd \|\|
	ShadowAEnd <= ShadowBStart);
	}
	}
	}
	return true;
	}
	#endif

	uptr VmaSize;

	static void initializeShadow() {
	verifyAddressSpace();

	// This is based on the assumption that the intial stack is always allocated
	// in the topmost segment of the user address space and the assumption
	// holds true on all the platforms currently supported.
	VmaSize =
	(MostSignificantSetBitIndex(GET_CURRENT_FRAME()) + 1);

	DCHECK(verifyShadowScheme());

	Mapping.initialize(ShadowScale[__esan_which_tool]);

	VPrintf(1, "Shadow scale=%d offset=%p\n", Mapping.Scale, Mapping.Offset);

	uptr ShadowStart, ShadowEnd;
	for (int i = 0; getShadowRegion(i, &ShadowStart, &ShadowEnd); ++i) {
	VPrintf(1, "Shadow #%d: [%zx-%zx) (%zuGB)\n", i, ShadowStart, ShadowEnd,
	(ShadowEnd - ShadowStart) >> 30);

	uptr Map = 0;
	if (__esan_which_tool == ESAN_WorkingSet) {
	// We want to identify all shadow pages that are touched so we start
	// out inaccessible.
	Map = (uptr)MmapFixedNoAccess(ShadowStart, ShadowEnd- ShadowStart,
	"shadow");
	} else {
	if (MmapFixedNoReserve(ShadowStart, ShadowEnd - ShadowStart, "shadow"))
	Map = ShadowStart;
	}
	if (Map != ShadowStart) {
	Printf("FATAL: EfficiencySanitizer failed to map its shadow memory.\n");
	Die();
	}

	if (common_flags()->no_huge_pages_for_shadow)
	NoHugePagesInRegion(ShadowStart, ShadowEnd - ShadowStart);
	if (common_flags()->use_madv_dontdump)
	DontDumpShadowMemory(ShadowStart, ShadowEnd - ShadowStart);

	// TODO: Call MmapNoAccess() on in-between regions.
	}
	}

	void initializeLibrary(ToolType Tool) {
	// We assume there is only one thread during init, but we need to
	// guard against double-init when we're (re-)called from an
	// early interceptor.
	if (EsanIsInitialized \|\| EsanDuringInit)
	return;
	EsanDuringInit = true;
	CHECK(Tool == __esan_which_tool);
	SanitizerToolName = "EfficiencySanitizer";
	CacheBinaryName();
	initializeFlags();

	// Intercepting libc _exit or exit via COMMON_INTERCEPTOR_ON_EXIT only
	// finalizes on an explicit exit call by the app. To handle a normal
	// exit we register an atexit handler.
	::__cxa_atexit((void (*)())finalizeLibrary);

	VPrintf(1, "in esan::%s\n", __FUNCTION__);
	if (__esan_which_tool <= ESAN_None \|\| __esan_which_tool >= ESAN_Max) {
	Printf("ERROR: unknown tool %d requested\n", __esan_which_tool);
	Die();
	}

	initializeShadow();
	if (__esan_which_tool == ESAN_WorkingSet)
	initializeShadowWorkingSet();

	initializeInterceptors();

	if (__esan_which_tool == ESAN_CacheFrag) {
	initializeCacheFrag();
	} else if (__esan_which_tool == ESAN_WorkingSet) {
	initializeWorkingSet();
	}

	EsanIsInitialized = true;
	EsanDuringInit = false;
	}

	int finalizeLibrary() {
	VPrintf(1, "in esan::%s\n", __FUNCTION__);
	if (__esan_which_tool == ESAN_CacheFrag) {
	return finalizeCacheFrag();
	} else if (__esan_which_tool == ESAN_WorkingSet) {
	return finalizeWorkingSet();
	}
	return 0;
	}

	void reportResults() {
	VPrintf(1, "in esan::%s\n", __FUNCTION__);
	if (__esan_which_tool == ESAN_CacheFrag) {
	return reportCacheFrag();
	} else if (__esan_which_tool == ESAN_WorkingSet) {
	return reportWorkingSet();
	}
	}

	void processCompilationUnitInit(void *Ptr) {
	VPrintf(2, "in esan::%s\n", __FUNCTION__);
	if (__esan_which_tool == ESAN_CacheFrag) {
	DCHECK(Ptr != nullptr);
	processCacheFragCompilationUnitInit(Ptr);
	} else {
	DCHECK(Ptr == nullptr);
	}
	}

	// This is called when the containing module is unloaded.
	// For the main executable module, this is called after finalizeLibrary.
	void processCompilationUnitExit(void *Ptr) {
	VPrintf(2, "in esan::%s\n", __FUNCTION__);
	if (__esan_which_tool == ESAN_CacheFrag) {
	DCHECK(Ptr != nullptr);
	processCacheFragCompilationUnitExit(Ptr);
	} else {
	DCHECK(Ptr == nullptr);
	}
	}

	unsigned int getSampleCount() {
	VPrintf(1, "in esan::%s\n", __FUNCTION__);
	if (__esan_which_tool == ESAN_WorkingSet) {
	return getSampleCountWorkingSet();
	}
	return 0;
	}

	} // namespace __esan